KR20220010975A - Electric motor assembly and hair dryer having the same - Google Patents

Abstract

The present invention relates to a motor assembly and a hair dryer including the same. According to the present invention, the motor assembly includes: an impeller; outer and inner housings arranged concentrically with each other; a stator accommodated in the inner housing; a rotor disposed inside the stator; a bearing for supporting a rotation shaft of the rotor; a bracket including a bearing accommodation part in which the bearing is accommodated, and a plurality of bridges spaced apart from each other in a circumferential direction on an outer surface of the bearing accommodation part and protruding in an axial direction so as to be coupled to the inner housing; and a vortex suppression part for blocking an empty space between the bridges so that generation of air vortices is suppressed. Accordingly, generation of vortices is suppressed in a region downstream of the impeller, and a flow loss caused by the generation of the vortices is reduced.

Description

A motor assembly and a hair dryer having the same

The present invention relates to a motor assembly and a hair dryer having the same.

As is well known, a motor is a device that converts electrical energy into mechanical energy. In general, a motor includes a stator and a rotor rotatably disposed inside or outside the stator.

Among the motors, it is important to reduce the size of a motor applied to a so-called handheld device or a handheld device (hereinafter referred to as a "handheld device") used by hand in consideration of handling convenience.

The above-described handheld device, for example, a motor applied to a hair dryer and/or a vacuum cleaner, is configured with an impeller to promote air movement or generate pressure.

The motor assembly having the impeller includes an outer housing for accommodating the impeller, an inner housing concentrically disposed inside the outer housing and forming an air flow path therebetween, and a plurality of connecting the outer housing and the inner housing. It is configured by having a vane, a stator and a rotor accommodated in the inner housing.

On the other hand, in the case of miniaturization by reducing the size and weight of the motor assembly having the impeller, high-speed rotation of the motor assembly having the impeller is required in order to maintain the same level of air flow.

However, in such a conventional motor assembly having an impeller, when a bearing is disposed on one side of the rotor, the lateral displacement of the rotor is increased. In particular, when operated at high speed (rotation), the lateral displacement is further increased, so that the wear of the bearing is remarkably increased, thereby significantly shortening the life of the bearing.

In consideration of this problem, when the bearings are installed on both sides of the rotor, a separate bracket for supporting the bearing is provided on one side of the rotor along the axial direction, and the separate bracket accommodates the bearing. It is configured to include a bearing accommodating part and a plurality of bridges spaced apart along the circumferential direction of the bearing accommodating part and extending in the axial direction.

However, in this conventional motor assembly having an impeller, when the impeller rotates, the air moved to the bracket forms a vortex (VORTEX) between the plurality of bridges of the bracket, resulting in an increase in flow path loss. There is a problem with doing it.

In addition, there is a problem that vibration and noise increase due to eddy currents between the plurality of bridges of the bracket.

US 20170170709 A1

Accordingly, an object of the present invention is to provide a motor assembly capable of suppressing vortex generation in a region downstream of an impeller and reducing flow loss due to vortex generation, and a hair dryer having the same.

Another object of the present invention is to provide a motor assembly capable of suppressing the addition of parts and suppressing vortex generation, and a hair dryer having the same.

Another object of the present invention is to provide a motor assembly capable of suppressing eddy current generation and promoting cooling of a stator coil, and a hair dryer having the same.

In the motor assembly according to the present invention for solving the above problems, bearings are provided on both sides of the rotor along the axial direction, and the vortex to block the empty space of the bracket supporting the half-load side bearing to suppress the occurrence of vortex It is characterized in that the suppression portion is provided.

Specifically, an impeller and an inner housing are provided inside the outer housing, a stator and a rotor are provided inside the inner housing, and a bearing receiving part for accommodating a bearing on one side of the rotor and a circumferential direction of the bearing receiving part A bracket having a plurality of bridges spaced apart is provided, and a vortex suppression unit for blocking the empty space between the plurality of bridges is provided, thereby suppressing the occurrence of a vortex due to the bracket when the air moved to the impeller passes through the bracket can do.

Thereby, the flow loss due to the vortex generation can be reduced, and the noise generation due to the vortex generation can be suppressed.

The impeller is provided on one inner side of the outer housing, and is disposed concentrically with the outer housing of the inner housing at one side of the impeller along the axial direction.

An air flow path through which air moves when the impeller rotates is formed between the outer housing and the inner housing.

A plurality of vanes for guiding the movement of air are provided between the outer housing and the inner housing.

The motor assembly may include an impeller; an outer housing in which the impeller is accommodated on one inner side; an inner housing concentrically disposed on the other inner side of the outer housing and having an air flow path formed on the outer side; a stator accommodated in the inner housing; a rotor accommodated in the stator and rotating the impeller; a bearing supporting the rotation shaft of the rotor; a bracket having a bearing accommodating part in which the bearing is accommodated and a plurality of bridges spaced apart from each other in the circumferential direction and protruding in the axial direction to be coupled to the inner housing; and a vortex suppressor for blocking an empty space between one side of the stator and the plurality of bridges along the axial direction so that the generation of a vortex of the air moved toward the bracket by the rotation of the impeller can be suppressed. do.

Here, the inner housing and the bracket are formed of a metal member.

The inner housing and the bracket may be made of, for example, aluminum (Al), copper (Cu), brass or zinc, or an alloy including at least one of these.

Here, the bearing receiving portion of the bracket is formed to have a reduced outer diameter compared to the outer diameter of the inner housing.

The plurality of bridges of the bracket are each provided with a radial section protruding from the outer surface of the bearing housing in a radial direction and an axial section bent from an end of the radial section and arranged in the axial direction.

Here, the axial section of the bracket may be coupled to the inner housing.

In one embodiment of the present invention, the plurality of bridges are implemented in three pieces spaced apart at equal angular intervals along the circumferential direction.

The stator may include a stator core; a stator coil wound around the stator core; and an insulator interposed between the stator core and the stator coil for insulation.

In one embodiment of the present invention, the vortex suppression portion is formed in the insulator.

The vortex suppressor is formed by extending one region of the insulator along the axial direction.

Accordingly, it is possible to prevent an increase in the number of parts by adding a separate part for suppressing the occurrence of vortex when the air moves.

The stator includes a stator core having a plurality of teeth and a stator coil wound around the stator core.

The stator coil includes a plurality of coil portions wound around the plurality of teeth.

The plurality of teeth is implemented as three.

The plurality of coil units is implemented in three pieces.

One end of the coil (wire) of the plurality of coil units is connected to a power source.

The other end of the coil (wire) of the plurality of coil units is connected to a neutral wire.

Here, one of the connecting pins of each pair may be connected to a power source, and the other may be connected to a neutral wire.

The vortex current suppression unit is provided on the outside of the plurality of coil units in a radial direction, respectively.

The lead-side wires of the plurality of coil units are connected to a connection pin connected to the power source.

The lead-out-side wires of the plurality of coil units are connected to a connection pin connected to the neutral wire.

In one embodiment of the present invention, a wire guide for guiding the wire of the stator coil is provided on at least one side along the circumferential direction of the vortex current suppressor.

The wire guides are respectively formed on both sides along the circumferential direction of the vortex current suppressor.

One of the wire guides guides the incoming-side wire of each coil part,

The other one of the wire guides guides the lead-out-side wire of each coil unit.

In an embodiment of the present invention, the vortex suppression unit is configured to include a creepage distance increasing section formed to be spaced apart from the plurality of bridges on the outside of the wire guide along the circumferential direction.

Thereby, the creepage distances of the lead-in side wire and the lead-out-side wire inside the vortex current suppressing part can be increased, respectively.

In one embodiment of the present invention, the outer surface of the vortex suppressor has an arc shape.

The radius of curvature of the outer surface of the vortex suppressor is formed to correspond to the outer diameter of the inner housing.

The radius of curvature of the outer surface of the vortex suppressor may be formed within a range of a preset width (upper limit or lower limit) compared to the radius of the inner housing.

That is, the outer surface of the vortex suppressor may be formed to be slightly larger or slightly smaller than the outer surface of the inner housing.

It may be preferable that the radius of curvature of the outer surface of the vortex suppressor is substantially the same as the radius of the inner housing.

The outer surface of the vortex suppressor may be disposed on an extension line of the outer surface of the inner housing along the axial direction.

Accordingly, the air moved along the outer surface of the inner housing can be continuously moved along the outer surface of the vortex suppressor without changing the direction.

Further comprising a PCB provided on one side of the bracket along the axial direction,

The PCB and the stator are connected by a plurality of connecting pins,

The plurality of connecting pins are configured to be coupled to each other through the vortex suppression unit.

The PCB is disposed to be spaced apart from the vortex current suppressor by a preset distance along the axial direction.

Thereby, cooling of the inside of the vortex suppression unit can be promoted by the reflux flow at the downstream end of the vortex suppression unit.

The end of the vortex suppressor is disposed on the same plane as the end of the bracket along the axial direction.

According to this configuration, since the downstream end of the vortex suppressor is spaced apart from the PCB like the downstream end of the bracket, some of the air moved along the outer surface of the vortex suppressor is moved to the inside of the vortex suppressor and the It is possible to cool the inside (space) of the vortex suppressor.

In an embodiment of the present invention, the vortex suppression unit is configured to include an extension section that protrudes relative to the bracket along the axial direction and extends so as to approach or contact the PCB.

Thereby, it is possible to further suppress the occurrence of a vortex of air passing through the vortex suppressor.

According to this configuration, flow loss due to vortex generation when the impeller is driven can be further suppressed.

In an embodiment of the present invention, an end of the extension section of the vortex suppressor may be configured to contact the PCB.

Accordingly, vortex generation may be further suppressed when the impeller is driven.

In an embodiment of the present invention, a penetrating portion is formed in the vortex current suppressing portion by penetrating the plate so that the inside and outside can communicate in the radial direction.

Thereby, heat dissipation inside the vortex suppressor may be promoted.

According to this configuration, the cooling of the stator and the rotor can be further promoted.

In one embodiment of the present invention, an insertion end cut out in the thickness direction to be inserted into the inner housing is formed at the end of the bridge.

Thereby, the occurrence of radial play of the bracket can be suppressed.

In one embodiment of the present invention, the stator includes a stator core, a stator coil wound around the stator core, and an insulator provided between the stator core and the stator coil to insulate the stator coil, and the insulator includes A bridge insertion part into which an end of the bridge is inserted is formed.

Thereby, the occurrence of circumferential play of the bridge of the bracket can be suppressed.

In one embodiment of the present invention, any one of the mutual contact surfaces of the bridge insertion part and the bridge is provided with a circumferential projection protruding in the circumferential direction, and the other one of the mutual contact surfaces of the bridge insertion part and the bridge has the circumference A circumferential direction projection receiving portion is provided so that the direction projection can be accommodated.

Thereby, coupling of the bracket, the insulator, and the inner housing may be facilitated.

In one embodiment of the present invention, it has a plurality of connecting pins protruding along the axial direction, further comprising a PCB provided on one side of the bracket,

The vortex current suppression unit may be formed of an electrical insulating member, one side formed on the plurality of connection pins, and the other side configured to be coupled to the stator.

Accordingly, it is possible to suppress an increase in the size of the mold of the insulator due to the formation of the vortex suppressor.

In an embodiment of the present invention, the stator includes a stator core, a stator coil wound around the stator core, and an insulator for insulating the stator coil,

The vortex suppressor may be configured to be in face-to-face contact with the insulator in an axial direction.

In one embodiment of the present invention, one of the mutual contact surfaces of the insulator and the vortex suppressor is provided with an axial projection protruding along the axial direction, and the other one of the mutual contact surfaces of the insulator and the vortex suppressor has the axial direction It is configured to be provided with an axial projection accommodating portion so that the projection can be accommodated.

Thereby, the occurrence of axial and radial play of the insulator and the vortex suppressor can be suppressed.

On the other hand, according to another field of the present invention, a hair dryer body provided with an air outlet; a handle having an air intake and connected in communication with the hair dryer body; and the motor assembly provided inside the handle.

Here, at least one of the hair dryer body and the handle is provided with an electric heater for heating air.

The electric heater may be provided inside the hair dryer body.

As described above, according to an embodiment of the present invention, a bearing disposed on one side of the rotor along the axial direction; a bracket having a bearing accommodating part in which the bearing is accommodated and a plurality of bridges formed to be spaced apart from each other in a circumferential direction around the bearing accommodating part; and a vortex current suppressor for blocking the empty space between the plurality of bridges, thereby suppressing the occurrence of a vortex caused by the bracket when the air moved by the impeller passes through the bracket.

In addition, the stator includes an insulator for insulating the stator core and the stator coil, and the vortex suppression unit is integrally formed with the insulator, thereby suppressing the addition of a separate component for suppressing the vortex.

In addition, since the outer surface of the vortex suppression unit has an arc shape, generation of a vortex due to the bracket when the air moved by the impeller passes through the bracket can be effectively suppressed.

In addition, since the radius of curvature of the outer surface of the vortex suppressor is formed to correspond to the radius of the inner housing, vortex generation can be more effectively suppressed.

In addition, the PCB and the vortex suppressor are formed to be spaced apart from each other along the axial direction, thereby forming a reflux flow at the downstream end of the vortex suppressing unit along the axial direction, thereby promoting cooling of the inner space of the vortex suppressing unit.

In addition, since the vortex suppressor has an extended section extending to be in contact with the PCB, it is possible to more effectively suppress the flow loss due to the vortex.

In addition, since the penetrating portion is formed through the plate surface so that the inside and outside of the vortex suppressor can communicate with each other, heat exchange between the inside and the outside of the vortex suppressor can be promoted.

In addition, the eddy current suppressor may be provided with a wire guide for guiding the wire of the stator coil, thereby suppressing the occurrence of contact between the wire and the bridge.

In addition, by providing a creepage distance increasing section spaced apart from the bridge of the bracket on the outside of the wire guide along the circumferential direction of the vortex suppressor, the insulation performance of the conductor (wire) inside the vortex suppressor can be improved.

In addition, a circumferential projection and a circumferential projection accommodating portion are provided between the insulator and the plurality of bridges, so that the occurrence of radial play between the insulator and the bracket may be suppressed.

In addition, the vortex current suppressing unit is configured to be coupled to the connecting pin of the PCB, and is configured to be coupled to the insulator when the connecting pin is connected, thereby suppressing an increase in the size of the mold of the insulator due to the formation of the vortex suppressing unit can do.

In addition, since the vortex current suppressing unit and the insulator are provided with an axial projection and an axial projection receiving portion protruding in an axial direction, a coupling force between the vortex current suppressing unit and the insulator may be increased.

1 is a cross-sectional view of a hair dryer having a motor assembly according to an embodiment of the present invention;
Figure 2 is a perspective view of the motor assembly of Figure 1;
3 is an exploded perspective view of the motor assembly of FIG. 1;
4 is an enlarged cross-sectional view of the motor assembly of FIG. 1;
5 is a perspective view for explaining the coupling relationship of the inner housing, the bracket, and the vortex suppressor of FIG. 3;
Figure 6 is a cross-sectional view of the vortex suppressor of Figure 5;
7 is a perspective view showing the inner surface of the vortex suppressor of FIG. 3;
8 is a modified example of the vortex suppressor and bracket of FIG. 3;
Fig. 9 is a side cross-sectional view of the bracket of Fig. 8;
10 is a cross-sectional view of the vortex suppressor of FIG. 8;
11 is a cross-sectional view of the coupling state of the vortex suppressor and the bracket of FIG. 8;
12 is a perspective view of a motor assembly according to another embodiment of the present invention;
13 is an exploded perspective view of FIG. 12;
Fig. 14 is a cross-sectional view of Fig. 12;
15 is a modified example of the vortex suppressor of FIG. 12;
16 is a cross-sectional view of FIG. 15;
17 is an exploded perspective view of a motor assembly according to another embodiment of the present invention;
18 is a perspective view of the coupled state of FIG. 17;
19 is an enlarged view of the main part of FIG. 17;
20 is a cross-sectional view of the coupling state of the axial projection and the axial projection receiving portion of FIG.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings. In this specification, even in different embodiments, the same and similar reference numerals are assigned to the same and similar components, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, in describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in the present specification, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the embodiments disclosed in the present specification, and should not be construed as limiting the technical spirit disclosed in the present specification by the accompanying drawings.

1 is a cross-sectional view of a hair dryer having a motor assembly according to an embodiment of the present invention. As shown in FIG. 1 , the hair dryer having the motor assembly of this embodiment has a hair dryer body 100 , a handle 150 provided in the hair dryer body 100 , and the inside of the handle 150 . It has a motor assembly 200 provided.

The hair dryer body 100 is formed with an air flow path 130 through which air moves therein.

An air outlet 135 through which air is discharged is provided at one side of the hair dryer body 100 .

The hair dryer body 100 includes an outer case 110 and an inner case 120 provided inside the outer case 110 .

The outer case 110 and the inner case 120 are implemented, for example, in a cylindrical shape, respectively.

The inner case 120 has a reduced size compared to the outer case 110 .

An outer surface of the inner case 120 is spaced apart from the inner surface of the outer case 110 , and an air flow path 130 through which air can move is formed between the outer surface of the inner case 120 and the outer case 110 . do.

The inner case 120 has a space 125 formed therein.

The space portion 125 of the inner case 120 is formed to have both sides open along the axial direction.

Accordingly, the air may be moved from one side to the other side along the inside of the space portion 125 of the inner case 120 .

An electric heater 140 is provided in the air passage 130 to heat the air.

The electric heater 140 includes a heat generating member 140a capable of generating heat by electric resistance heat when power is supplied. The heating member 140a may be implemented with, for example, a nichrome wire.

A main PCB 145 connected to the electric heater 140 may be provided inside the hair dryer body 100 . The main PCB 145 may be configured to include, for example, a program capable of controlling the respective operations of the electric heater 140 and the motor assembly 200 .

Although not specifically shown in the drawings, the hair dryer body 100 and/or the handle 150 is provided with a signal input unit (button) for inputting an operation signal, and the main PCB 145 is provided with an operation signal. The signal input unit for inputting may be connected to be capable of transmitting a signal.

Accordingly, the main PCB 145 may control the motor assembly 200 and the electric heater 140, respectively, based on the control signal input through the signal input unit.

A handle 150 is provided on one side of the hair dryer body 100 .

The handle 150 has an accommodating space 155 formed therein.

The handle 150 is configured to allow air to move along the inside.

One end (top in the drawing) of the handle 150 is connected to the hair dryer body 100 .

The handle 150 is connected in communication with the hair dryer body (100).

Thereby, the air passing through the inside of the handle 150 can be moved to the inside of the hair dryer body (100).

The handle 150 is provided with an air intake 160 so that external air can be sucked into the inside.

The air inlet 160 may be formed, for example, at the lower end of the handle 150 .

The motor assembly 200 may be disposed on a downstream side of the air intake port 160 .

Accordingly, the air sucked in through the air inlet 160 may be moved downstream via the motor assembly 200 .

The motor assembly 200 is provided inside the handle 150 .

The handle 150 is provided with a cable 165 connected to an external power source (commercial power source).

The cable 165 may be connected to the motor assembly 200 and the main PCB 145 .

Accordingly, power may be supplied to the motor assembly 200 , the main PCB 145 , and the electric heater 140 , respectively.

The motor assembly 200 includes an impeller 210 and an impeller driving unit 278 for driving the impeller 210 . The impeller driving unit 278 is, for example, a stator 280 and a rotor 340 connected to the impeller 210 and rotatably disposed with a predetermined gap G with respect to the stator 280. provided and composed.

With this configuration, when the impeller 210 is rotated when the motor assembly 200 is driven, external air is sucked into the handle 150 through the air inlet 160 , and the handle 150 is ) The air passing through the inside is moved to the inside of the hair dryer body (100).

The air moving along the internal air flow path 130 of the hair dryer body 100 may be heated during operation of the electric heater 140 and discharged to the outside through the air outlet 135 . When heated air or air at room temperature (when the electric heater 140 is not in operation) is discharged through the air outlet 135 , air around the air outlet 135 may be combined.

When air is discharged through the air outlet 135 , the air inside the inner case 120 and the air around the air outlet 135 of the outer case 110 are discharged through the air outlet 135 . It can be moved by mixing with air.

FIG. 2 is a perspective view of the motor assembly of FIG. 1 , FIG. 3 is an exploded perspective view of the motor assembly of FIG. 1 , and FIG. 4 is an enlarged cross-sectional view of the motor assembly of FIG. 1 . 2 to 4, the motor assembly 200 includes an impeller 210, a housing 250, an impeller driving unit 278, a first bearing 360a, a second bearing 360b, and a bracket. (380) and a vortex suppression unit (450).

The impeller 210 includes a hub 215 and a plurality of blades 220 disposed around the hub 215 .

The hub 215 has a cylindrical shape. A rotation shaft hole 217 is formed in the hub 215 so that a rotation shaft 341 of a rotor 340, which will be described later, can be inserted. The plurality of blades 220 protrude from the circumference of the hub 215 in a radial direction and are arranged to be spaced apart from each other in the circumferential direction.

The impeller 210 is, for example, configured to rotate counterclockwise in the drawing.

The impeller 210 is configured to promote the movement of air in the axial direction during rotation.

The housing 250 includes an outer housing 251 and an inner housing 260 that are arranged concentrically with each other.

The housing 250 may be formed of a metal member.

The outer housing 251 has a cylindrical shape, and the impeller 210 is rotatably accommodated inside one side.

An impeller accommodating space 252 is formed on one inner side (left side of FIG. 4 ) of the outer housing 251 .

The inner housing 260 is provided at one side of the impeller 210 inside the outer housing 251 .

In FIG. 4 , along the movement direction of the air moved by the impeller 210 , the left side of the drawing in which the impeller 210 is disposed may be the upstream side, and the right side of the drawing in which the PCB is disposed may be the downstream side.

The inner housing 260 is disposed on the downstream side of the impeller accommodating space 252 along the movement direction of the air moved when the impeller 210 rotates.

The inner housing 260 is configured to have a reduced outer diameter compared to the inner diameter of the outer housing 251 .

The inner housing 260 may be configured such that, for example, one end (left end in the drawing) is blocked and the other end (right end in the drawing) is open.

The inner housing 260 is configured to protrude to the outside of the outer housing 251 .

An air passage 257 is formed between the inner housing 260 and the outer housing 251 .

A plurality of guide vanes 270 for guiding the movement of air are provided in the air movement passage.

The guide vane 270 may be provided inside the outer housing 251, for example.

The impeller driving unit 278 includes, for example, a stator 280 and a rotor 340 rotatably disposed with respect to the stator 280 .

The stator 280 includes, for example, a stator core 290 and a stator coil 300 wound around the stator core 290 .

The stator core 290 may be configured by, for example, insulating and stacking a plurality of electrical steel plates 292 .

The plurality of electrical steel plates 292 of the stator core 290 may be each provided with a circular yoke 294 and a plurality of teeth 295 protruding radially from the inner surface of the yoke 294 . . The plurality of teeth 295 may be implemented as, for example, three.

The stator coil 300 may, for example, be implemented as a so-called centralized winding that is intensively wound around the plurality of teeth 295 . The stator coil 300 may include three coil units 300a wound around the three teeth 295, respectively.

Here, each of the three coil units 300a is wound in a predetermined number of turns around the lead-in side wire 301a and each tooth 295, which is drawn in to be wound around the respective teeth 295, and then drawn out again. It is configured to be provided with each of the lead-out-side wires 301b.

The stator coil 300 may be configured such that the three coil units 300a are respectively connected to respective phases (U-phase, V-phase, and W-phase) of a three-phase alternating current that is a supply power.

The lead-in wire 301a of each coil part 300a is respectively connected to each phase (U-phase, V-phase, W-phase) of the power source, and the lead-side wire 301b of each coil part 300a is a neutral wire. are each connected to

The stator 280 may be rotatably implemented at a high speed, for example, 150 to 185KRPM.

The stator 280 includes an insulator 320 to insulate the stator coil 300 .

The insulator 320 may be interposed between the stator core 290 and the stator coil 300 , for example.

The rotor 340 may include, for example, a rotating shaft 341 and a permanent magnet 345 rotatable about the rotating shaft 341 .

The rotation shaft 341 may be configured to protrude from both sides of the permanent magnet 345 , for example.

Bearings 360 rotatably supporting the rotation shaft 341 are provided on both sides of the rotor 340 , respectively.

The bearing 360 may include, for example, a first bearing 360a and a second bearing 360b.

The first bearing 360a may be disposed on an upstream side of the permanent magnet 345 along a moving direction of air, for example.

The second bearing 360b may be disposed on a downstream side of the permanent magnet 345 along a moving direction of air, for example.

A first bearing coupling part 265 is provided in the inner housing 260 so that the first bearing 360a can be received and coupled.

The first bearing 360a and the second bearing 360b may be implemented as ball bearings.

The bearing 360 (first bearing 360a, second bearing 360b) includes, for example, an outer ring 361, an inner ring 363 concentrically disposed inside the outer ring 361, and the A plurality of balls 365 provided between the outer ring 361 and the inner ring 363 may be provided.

The bearing 360 is, for example, configured to have an outer diameter reduced compared to the outer diameter of the inner housing 260 .

The bearing 360 has, for example, an outer diameter smaller than the outer diameter of the stator 280 .

The bearing 360 may be configured to have an outer diameter slightly larger than the outer diameter of the permanent magnet 345 , for example.

Meanwhile, the stator 280 may be inserted and coupled to the inside of the inner housing 260 .

A coupling protrusion 297 protruding outward along the radial direction may be formed on the outer surface of the stator core 290 . The coupling protrusion 297 may be implemented to extend in the axial direction. The coupling protrusion 297 may be configured in plurality to be spaced apart along the circumferential direction of the stator 280 . The coupling protrusion 297 may be implemented as, for example, one. In this embodiment, although the case in which the coupling protrusion 297 is implemented as one is illustrated, this is only an example, and the number may be composed of a plurality of pieces.

A slot 267 may be provided in the inner housing 260 to allow the coupling protrusion 297 of the stator 280 to be inserted.

Accordingly, the stator 280 may be assembled and coupled to a predetermined position inside the inner housing 260 .

The slot 267 may be configured to be cut (cut off) to extend along the axial direction. The slot 267 may be implemented as one, for example, in the same way as the coupling protrusion 297 .

The second bearing 360b is provided on the downstream side of the stator 280 and the rotor 340 .

The second bearing 360b may be supported by the bracket 380 .

The bracket 380 includes, for example, a bearing receiving portion 381 in which the second bearing 360b is accommodated and a plurality of bridges 390 extending in the axial direction from the bearing receiving portion 381 , can be configured.

Accordingly, a reflux occurs in which the air moving in the axial direction along the outer surface of the inner housing 260 moves inward (center side) in the radial direction, which may result in a flow loss.

The bracket 380 may be formed of a metal member.

Here, the inner housing 260 and the bracket 380 may be made of, for example, aluminum (Al), copper (Cu), brass, or zinc (Zn).

The inner housing 260 and the bracket 380 may be made of an alloy including at least one of aluminum (Al), copper (Cu), brass, or zinc (Zn).

The bearing accommodating part 381 may be configured to have, for example, an outer diameter reduced compared to the outer diameter of the inner housing 260 .

The bearing receiving portion 381 may be formed so that the upstream end is open and the downstream end is blocked.

Accordingly, the second bearing 360b may be coupled from the upstream side.

A through hole 385 may be formed at the downstream end of the bearing receiving part 381 through the plate surface.

The through hole 385 may be formed to be smaller than the outer diameter of the inner ring 363 of the bearing 360 , for example.

The plurality of bridges 390 may include, for example, three.

The plurality of bridges 390 may be configured to be spaced apart from each other at equal angular intervals (eg, 120 degree intervals in this embodiment) along the circumferential direction. In this embodiment, although the case where the plurality of bridges 390 is implemented as three is illustrated, this is only an example, and the number may be formed of two or more than four.

The plurality of bridges 390 are, for example, a radial section 391 protruding from the outer surface of the bearing receiving part 381 in a radial direction, and an axial direction bent from the radial section 391 to extend in the axial direction. It may be configured with a section 392 .

Here, the maximum outer diameter of the bracket 380 (bridge 390) may be configured to be the same as the outer diameter of the inner housing 260, for example.

The plurality of bridges 390 may be configured so that, for example, an end is in contact with an end of the stator 280 .

The plurality of bridges 390 may each have an insertion end 394 to be inserted into the inner housing 260 .

The insertion end 394 may be configured to be cut along the thickness direction so that the outer diameter can be reduced.

The insertion end 394 may have a preset length along the axial direction.

Here, each of the bridges 390 may include the insertion end 394 and a protruding end 395 protruding in a radial direction from the insertion end 394 , respectively.

A bridge insertion part 325 may be formed in the insulator 320 so that the bridge 390 (insertion end 394) of the bracket 380 can be inserted.

The bridge insertion part 325 is formed to correspond to the number of bridges 390 of the bracket 380 .

In this embodiment, the bridge insertion part 325 is implemented in three pieces.

The bridge insertion part 325 may be configured to have an outer surface (outer surface) corresponding to the inner surface (inner surface) of each of the bridges 390 .

The bridge insertion part 325 may be reduced in a radial direction and formed to extend in an axial direction.

The bridge insertion part 325 has a shape in which the downstream end is opened along the axial direction.

Thereby, the bridge 390 may be inserted and coupled along the axial direction from the downstream end of the bridge insertion part 325 .

The insertion end 394 of each bridge may be configured such that, for example, three surfaces including both side surfaces and an inner surface of the bridge insertion portion 325 are in contact with each other.

A bridge coupling part 269 may be formed in the inner housing 260 so that a region of the bridge 390 (protruding end 395) of the bracket 380 can be inserted and coupled.

An area of the protruding end 395 of the bridge 390 is inserted into the bridge coupling part 269 to a preset depth.

The bridge coupling portion 269 of the inner housing 260 may be cut to a predetermined length along the axial direction from the downstream end.

The bridge coupling portion 269 of the inner housing 260 has a width corresponding to the width of the bridge 390 of the bracket 380, respectively.

The insertion end 394 of each bridge 390 of the bracket 380 is inserted into the inner housing 260, and the end protruding from the insertion end 394 of the bridge 390 in the radial direction is They are respectively inserted and coupled to the bridge coupling portions 269 of the inner housing 260 .

Accordingly, the coupling force between the stator 280 , the inner housing 260 and the bracket 380 may be improved.

Accordingly, occurrence of displacement of the second bearing 360b may be suppressed, and shortening of life due to occurrence of lateral displacement of the second bearing 360b may be suppressed.

In addition, the air gaps of the rotor 340 and the stator 280 may be uniformly maintained, and high-speed operation of the rotor 340 may be possible.

Meanwhile, a printed circuit board (PCB) 430 may be provided on one side (right side in FIG. 4 ) of the bracket 380 .

The PCB 430 may be electrically connected to the stator coil 300 , for example.

The PCB 430 may be configured to include, for example, a control program for controlling currents having different frequencies to be applied.

Thereby, it is possible to change (adjust) the number of rotations (rotational speed) of the rotor 340 (impeller 210).

The PCB 430 may be provided with a plurality of connection pins 433 protruding along the axial direction.

In the PCB 430 , for example, a plurality of connection pin holes 432 may be respectively formed through the plate surface so that the plurality of connection pins 433 can be inserted and coupled.

Each of the plurality of connection pins 433 is formed of an electric conductor.

An electric circuit electrically connected to the connection pin 433 is configured in the PCB 430 .

The PCB 430 may be configured to have, for example, a “Y” shape branched in three directions. In the present embodiment, the case in which the PCB 430 is implemented in a “Y” shape is exemplified, but this is only an example and may be configured in a circular or other shape.

The plurality of connection pins 433 may be implemented, for example, in number of six.

The plurality of connection pins 433 may be implemented in three pairs, for example.

The three pairs of connecting pins 433 may be spaced apart from each other in the circumferential direction to correspond to each other between the plurality of bridges 390 .

With this configuration, when the impeller 210 rotates, the air on the upstream side of the impeller 210 moves to the downstream side of the impeller 210 . The air moved to the downstream side of the impeller 210 is guided to the downstream side of the inner housing 260 by the guide vane 270 .

The air guided to the downstream side of the inner housing 260 may pass through the bracket 380 and move to the downstream side of the bracket 380 . At this time, some of the air passing through the bracket 380 is moved inward along the radial direction between the plurality of bridges 390 (space) of the bracket 380 to form a rotating vortex, resulting in flow Not only losses are generated, but also noise is increased due to the vortex generation.

The motor assembly 200 of an embodiment of the present invention is configured by having a vortex current suppressor 450 that blocks between the plurality of bridges 390 of the bracket 380, so that the movement of air by the impeller 210 In this case, it is possible to suppress the occurrence of eddy currents caused by the bracket 380 . Accordingly, it is possible to suppress the generation of flow loss due to the vortex generation of the bracket 380, and the noise generation due to the vortex generation can be suppressed.

In an embodiment of the present invention, the vortex current suppressor 450 may be configured to be provided on the stator 280 , for example.

The vortex current suppressor 450 may be formed in the insulator 320 , for example.

More specifically, the vortex current suppressor 450 may be formed at the downstream end of the insulator 320 .

In this embodiment, the insulator 320 includes a first insulator 320a provided on an upstream side of the stator 280 and a second insulator 320b provided on a downstream side of the stator 280, The vortex suppression part may be formed to be provided at a downstream end of the second insulator 320b.

In this embodiment, the case in which two insulators are configured is exemplified, but this is only an example, and the insulator may be configured as one. In this case, the vortex current suppressor 450 may be formed at the downstream end of the one insulator.

The vortex suppressor 450 may be configured such that one region of the insulator 320 protrudes in the axial direction to be disposed between the plurality of bridges 390 of the bracket 380 .

In the present embodiment, the vortex current suppressor 450 may be integrally formed with the second insulator 320b.

Thereby, it can be suppressed from increasing the assembly man-hours by adding a separate component to form the vortex current suppressing portion 450 that blocks between the plurality of bridges 390 of the bracket 380 .

The outer surface of the vortex suppressor 450 may be configured to have a circular arc cross-section.

The coil parts 300a of the stator coil 300 may be respectively disposed inside the vortex current suppression part 450 .

The vortex current suppression unit 450 may be configured to correspond to between the three bridges 390 .

The vortex current suppression unit 450 may be formed by extending the insulator 320 disposed on the outside of each coil unit 300a of the stator coil 300 in the axial direction.

A bridge accommodating space in which the bridge 390 of the bracket 380 is accommodated may be formed between the vortex current suppression part 450 .

Each of the vortex current suppression units 450 may be configured to have a corresponding circumferential length (arc length) between the three bridges 390, respectively.

The vortex current suppression unit 450 may be configured such that the downstream end is disposed on the same plane as the downstream end of the bracket 380 .

That is, one end of the vortex suppressor 450 is connected to the insulator 320 and the other end (downstream end) extends along the axial direction to be the same as the downstream end of the bracket 380. have.

The connection pin 433 of the PCB 430 may be coupled to the vortex suppressor 450 to be inserted to a preset depth.

Any one of the pair of connecting pins 433 connected to each of the vortex current suppression units 450 may be respectively connected to the lead-side wire 301a of each coil unit 300a of the stator coil 300 .

The other one of the pair of connecting pins 433 connected to each of the vortex current suppressing units 450 may be respectively connected to the lead-side wire 301b of each coil unit 300a of the stator coil 300 .

5 is a perspective view for explaining the coupling relationship of the inner housing, the bracket, and the vortex suppressor of FIG. 3 , FIG. 6 is a cross-sectional view of FIG. 5 , and FIG. 7 is a perspective view showing the inside of the vortex suppressor of FIG. As shown in FIG. 5 , the vortex current suppressor 450 is provided in a region downstream of the inner housing 260 along the moving direction of the air. The brackets 380 (bridges 390) are respectively coupled between the vortex current suppression units 450 .

In the bracket 380, the insertion ends 394 of the plurality of bridges 390 are inserted into the inner housing 260, and the projecting ends 395 of the plurality of bridges 390 are inserted into the inner housing ( Each is coupled to the inside of the bridge coupling portion 269 of the 260).

Meanwhile, each of the vortex current suppressing units 450 has an arc cross-sectional shape, as shown in FIG. 6 .

The vortex current suppression unit 450 is disposed so that an empty space is formed therein.

The inner surface of the vortex suppression unit 450 is configured to be spaced apart from the outer surface of the rotation shaft 341 by a preset distance.

The inner surface of the vortex current suppressor 450 may be configured to be the same as the inner surface of the insulator 320 or to be expanded than the inner surface of the insulator 320 .

The inner surface of the vortex current suppression unit 450 may be disposed outside the outer surface of each coil unit 300a of the stator coil 300 .

The plurality of connecting pins 433 are respectively inserted and coupled to the vortex current suppression unit 450 .

The vortex current suppressor 450 has a greater thickness than the plurality of connection pins 433 .

The vortex suppressor 450 is configured to have an outer diameter that is expanded compared to the outer diameter of the insulator 320 .

Here, the outer diameter of the insulator 320 is disposed inside the inner housing 260 , and the outer surface of the vortex current suppression part 450 is disposed on an extension line of the outer surface of the inner housing 260 , so that the vortex current suppression The outer surface of the part 450 is expanded compared to the outer surface of the insulator 320 to correspond to the thickness of the inner housing 260 .

An outer surface of the vortex current suppressing unit 450 is disposed to correspond to an outer diameter of the inner housing 260 .

An outer surface (outer diameter) of the vortex current suppression unit 450 is configured to be substantially the same as an outer diameter of the inner housing 260 .

Accordingly, the occurrence of a flow loss of the air moved by the rotation of the impeller 210 may be suppressed.

On the other hand, the eddy current suppressor 450 is provided with a wire guide 455 for guiding the wire 301 extending from the stator coil (300).

The wire guides 455 are respectively formed on both sides along the circumferential direction of the vortex current suppressor 450 .

Here, the wire guide 455 is configured to guide the incoming-side wire 301a and the outgoing-side wire 301b of each coil portion 300a of the stator coil 300 , respectively.

The wire guide 455 is formed to protrude inward along the radial direction on the inner surface of the vortex current suppressor 450 .

The wire guide 455, as shown in FIG. 7, is configured to protrude radially from the inner surface of the vortex suppressor 450 and extend in the axial direction.

Thereby, the unexpected movement of the wire 301 provided on the inside of the wire guide 455 toward the bracket 380 (bridge 390) can be suppressed.

The lead-in side wire 301a and the outgoing-side wire 301b of each coil part 300a of the stator coil 300 are electrically connected to a connection pin 433 disposed adjacent among the plurality of connection pins 433, respectively. connected

The lead-in wire 301a of each coil part 300a is electrically wound at least once or several times by, for example, the connection pin 433 coupled to one side of the vortex current suppression part 450 . can be connected

The lead-side wire 301b of each coil unit 300a is wound at least once or several times by, for example, the connection pin 433 coupled to the other side of the vortex current suppression unit 450 by winding it at least once or several times. can be connected to

The lead-in shaft wire 301a and the lead-side wire 301b may be detached so that a contact area with the connection pin 433 can be energized.

With this configuration, the first bearing 360a is received and coupled to the first bearing coupling part 265 inside the inner housing 260, and the stator 280 is inside the inner housing 260. Acceptance is combined. The stator 280 is inserted and coupled in the axial direction in a state in which the coupling protrusion 297 is inserted into the slot 267 of the inner housing 260 . The rotor 340 is coupled to the inside of the stator 280 .

Meanwhile, the second bearing 360b may be coupled to the rotation shaft 341 of the rotor 340 , and the bracket 380 may be coupled to accommodate the second bearing 360b therein.

The bracket 380 may be inserted and coupled along the axial direction in a state in which a plurality of bridges 390 are respectively disposed to correspond to each other between the vortex current suppression units 450 .

More specifically, the insertion end 394 of each bridge 390 of the bracket 380 is respectively inserted into the inner housing 260 and the bridge insertion portion 325 of the insulator 320 .

When each of the bridges 390 is continuously inserted, the protruding end 395 of each of the bridges 390 is inserted and coupled to the inside of the bridge coupling portion 269 of the inner housing 260 .

The PCB 430 may be coupled to each end of each connection pin 433 of the vortex current suppressor 450 . An end of each connection pin 433 may be inserted and coupled to a corresponding connection pin hole 432 of the PCB 430 .

Meanwhile, the operation is started, and power of a frequency preset by the PCB 430 may be supplied to the stator coil 300 . Accordingly, a rotating magnetic field is formed in the stator coil 300 and interacts with the magnetic field formed by the permanent magnet 345 , so that the rotor 340 can be rotated about the rotating shaft 341 . When the rotor 340 is rotated, the impeller 210 is rotated, and the air upstream of the outer housing 251 by the impeller 210 passes through the impeller 210 of the impeller 210 . It can be moved downstream.

The air moved downstream by the impeller 210 is guided by the guide vane 270 and moves downstream of the inner housing 260 along the outer surface of the inner housing 260 .

At this time, since the outer surfaces of the plurality of bridges 390 of the vortex current suppressor 450 and the bracket 380 have the same outer diameter as the inner housing 260, the air moved along the inner housing 260 has a radius It can be moved linearly and continuously along the outer surfaces of the vortex current suppressor 450 and the bridge 390 without moving inward (vortex flow) along the direction.

Accordingly, generation of a vortex when the air moved downstream by the impeller 210 passes through the bracket 380 may be suppressed.

According to this configuration, the occurrence of a flow loss of air by the impeller 210 can be suppressed. In addition, noise generation due to the generation of the vortex can be suppressed.

On the other hand, the rotor 340 is supported by the first bearings 360a and the second bearings 360b provided on both sides of the rotor 340 along the axial direction, so that when the rotor 340 rotates, the lateral Generation of directional displacement can be suppressed.

In addition, in the bracket 380, the insertion end 394 of the plurality of bridges 390 is supported by the insulator 320 and the inner housing 260, and the protruding end 395 of each bridge 390 is By being coupled and supported inside the bridge coupling portion 269 of the inner housing 260 , the bearing receiving portion 381 of the bracket 380 may be prevented from being displaced in the lateral direction.

Accordingly, the occurrence of lateral displacement of the rotation shaft 341 and the rotor 340 may be suppressed, and the air gap G of the rotor 340 and the stator 280 may be uniformly and stably maintained.

8 is a modified example of the vortex suppressor and bracket of FIG. 3, FIG. 9 is a side view of the bracket of FIG. 8, FIG. 10 is a cross-sectional view of the vortex suppressor of FIG. 8, and FIG. 11 is the vortex suppressor and bracket of FIG. It is a cross-sectional view of the bonding state of As shown in FIG. 8 , the motor assembly 200a according to another embodiment of the present invention includes an impeller 210 , a housing 250 , an impeller driving unit 278 , a bearing 360 , a bracket 380a and a vortex. A suppressor 450 is provided.

The housing 250 includes an outer housing 251 and an inner housing 260 that are arranged concentrically with each other.

A plurality of guide vanes 270 are provided between the outer housing 251 and the inner housing 260 .

As described above, the bearing 360 includes a first bearing 360a and a second bearing 360b respectively disposed on both sides of the rotor 340 in the axial direction.

The impeller driving unit 278 is, for example, provided with a stator 280 and a rotor 340 that is rotatably disposed with a gap G with respect to the stator 280 and rotates the impeller 210. is composed

The stator 280 includes a stator core 290 , a stator coil 300 wound around the stator core 290 , and an insulator 320 for insulating the stator coil 300 .

A bracket 380a for supporting the second bearing 360b is provided on one side (downstream side) of the rotor 340 in the axial direction.

The bracket 380a is, for example, a bearing receiving portion 381 for receiving and supporting the second bearing 360b and protruding from the bearing receiving portion 381 in a radial direction and bent to extend in the axial direction It is configured with a plurality of bridges (390).

The plurality of bridges 390 are spaced apart at equal angular intervals and are implemented in three pieces.

The insulator 320 is formed with a vortex suppressor 450 extending in the axial direction to be disposed between the plurality of bridges 390 of the bracket 380a.

The vortex suppressor 450 has a circular arc cross-sectional shape.

A wire guide 455 protruding inward along the radial direction is provided inside the vortex suppressor 450 .

The wire guides 455 are respectively provided on both sides along the circumferential direction of the vortex current suppressor 450 .

A creepage distance increasing section 460 spaced apart from each bridge 390 of the bracket 380a by a preset width w is formed in the vortex current suppression unit 450, respectively.

Thereby, the creepage distance of the wire 301 disposed inside the vortex current suppression unit 450 and guided by the wire guide 455 may be increased.

The circumferential length of the vortex suppressor 450 is formed by subtracting twice the spacing width w of the creepage distance increasing section 460 from the circumferential length between the bridges 390 of the bracket 380. can be

A pair of connecting pins 433 are provided in the vortex current suppression unit 450 .

A PCB 430 is disposed on one side (downstream side of the air movement direction) of the bracket 380a along the axial direction.

The PCB 430 may include, for example, a control program for controlling the operation of the impeller driving unit 278 (the stator 280 and the rotor 340 ).

The PCB 430 is coupled to each connection pin 433 of the vortex suppressor 450 .

On the other hand, the insulator 320 has a bridge insertion portion 3251 is formed so that the end of each bridge 390 of the bracket 380a can be inserted.

Insertion ends 394 are formed in each bridge 390 of the bracket 380a so as to be inserted into the bridge insertion portions 3251 of the inner housing 260 and the insulator 320 .

Each insertion end 394 of the bridge 390 is cut in the thickness direction so that the outer diameter can be reduced.

A protruding end 395 is formed on one side of the insertion end 394 of each bridge 390 of the bracket 380a.

A cut-out bridge coupling part 269 is formed in the inner housing 260 so that a region (upstream end) of the protruding end 395 of each bridge 390 can be inserted and coupled.

Meanwhile, circumferential projections 396 protruding in the circumferential direction are formed on any one of the mutual contact surfaces of each insertion end 394 of the bracket 380a and the bridge insertion portion 3251 of the insulator 320 .

The circumferential projection 396 may be formed, for example, on both sides of the insertion end 394 of each bridge 390 of the bracket 380a.

The circumferential projection 396 may be formed to extend along the axial direction.

On the other one of the mutual contact surfaces of each insertion end 394 of the bracket 380a and the bridge insertion portion 3251 of the insulator 320, the circumferential projection accommodating portion so that the circumferential projection 396 can be accommodated, respectively. (327) are respectively formed.

The circumferential projection accommodating part 327 may be respectively recessed on both sides of the bridge insertion part 3251 of the insulator 320 .

The circumferential projection receiving portion 327 may be formed to extend in the axial direction.

According to this configuration, each insertion end 394 of the bridge 390 of the bracket 380a can be coupled to the inside of the bridge insertion portion 3251 of the insulator 320 at an accurate position.

Accordingly, the insertion end 394 of each bridge 390 of the bracket 380a can be smoothly inserted and coupled to the inside of the inner housing 260 without being spread outward in the radial direction.

12 is a perspective view of a motor assembly according to another embodiment of the present invention, FIG. 13 is an exploded perspective view of FIG. 12 , and FIG. 14 is a cross-sectional view of FIG. 12 . The motor assembly 200b of another embodiment of the present invention includes an impeller 210, a housing 250, an impeller driving unit 278, a bearing 360, a bracket 380, a PCB 430 and a vortex suppression unit 450a. It is constituted by providing

The housing 250 includes an outer housing 251 and an inner housing 260 that are concentrically disposed with each other.

The impeller driving unit 278 includes a stator 280 and a rotor 340 disposed with a predetermined gap G with respect to the stator 280 .

The rotor 340 includes a rotating shaft 341 and a permanent magnet 345 .

The rotation shaft 341 is configured to extend to both sides of the permanent magnet 345 .

The rotation shaft 341 is rotatably supported by bearings 360 disposed on both sides of the rotor 340 .

The bearing 360 includes a first bearing 360a and a second bearing 360b that are spaced apart from each other in the axial direction.

The first bearing 360a may be provided inside the inner housing 260 , for example.

The second bearing 360b may be provided on a downstream side of the permanent magnet 345 , for example.

The stator 280 and the rotor 340 are received and coupled to the inside of the inner housing 260 .

The stator 280 includes a stator core 290 , a stator coil 300 wound around the stator core 290 , and an insulator 320 for insulating the stator coil 300 .

A bracket 380 for receiving and supporting the second bearing 360b is provided on a downstream side of the rotor 340 (permanent magnet 345) along the moving direction of the air.

The bracket 380 includes a bearing accommodating portion 381 to which the second bearing 360b is received and coupled, and a plurality of bridges 390 spaced apart from each other around the bearing accommodating portion 381 .

The plurality of bridges 390 include a radial section 391 protruding in the radial direction of the bearing receiving portion 381 and an axial section 392 bent from the radial section 391 and extending in the axial direction. do.

On the other hand, the insulator 320 is formed with the vortex current suppressor 450a to block between the plurality of bridges 390 of the bracket 380 to suppress the vortex generation.

The vortex current suppression part 450a has a circular arc cross section.

The outer surface of the vortex current suppression portion 450a is configured to have the same outer diameter as the outer diameter of the inner housing (260).

The vortex current suppression portion 450a is formed to protrude from the downstream end of the bracket 380 in the axial direction.

Accordingly, it is possible to further suppress the occurrence of a vortex when the air moved by the impeller 210 moves.

Here, among the entire length of the vortex current suppression unit 450a, a section that extends further than the downstream end of the bracket 380 may be referred to as an extension section 470 .

The outer surface of the extension section 470 of the vortex suppressor 450a is provided on the same line as the outer surface of the vortex suppressor 450a.

A length in the circumferential direction of the extension section 470 of the vortex suppressor 450a is the same as the length in the circumferential direction of the vortex suppressor 450a.

The vortex suppressor 450a may be formed to have the same thickness over the entire length, or may be configured to have different thicknesses.

More specifically, for example, the thickness of the extension section 470 disposed on the downstream side of the bracket 380 may be thinner than that of the section disposed on the upstream side of the vortex current suppression part 450a.

The vortex current suppressing part 450a has an extension section 470 that further extends in the axial direction from the downstream end of the bracket 380, so that the entire circumferential area along the circumferential direction on the downstream side of the bracket 380 is provided. Among the generated eddy currents, it is possible to reduce eddy currents generated between the bridges 390 .

Accordingly, the occurrence of a flow loss of the air moved by the impeller 210 can be further suppressed.

A pair of connecting pins 433 protrude from each of the vortex current suppressing parts 450a.

The PCB 430 is coupled to an end of a pair of connecting pins 433 of each of the vortex current suppressing units 450a.

Wires 301a and 301b of each coil part 300a of the stator coil 300 are connected to a pair of connecting pins 433 of each of the vortex current suppression parts 450a to be energized, respectively.

FIG. 15 is a modified example of the vortex suppressor of FIG. 12 , and FIG. 16 is a cross-sectional view of FIG. 15 . The motor assembly 200b of this embodiment, as described above, includes the impeller 210, the housing 250, the impeller driving unit 278, the second bearing 360b, the bracket 380 and the vortex suppression unit 450b. be prepared

As described above, the housing 250 includes an outer housing 251 and an inner housing 260 that are concentrically disposed with each other.

The impeller driving unit 278 is, for example, disposed with a stator 280 accommodated in the inner housing 260 and a gap G with the stator 280 and rotating the impeller 210 Consists of a rotor 340 .

The stator 280 includes a stator core 290 , a stator coil 300 wound around the stator core 290 , and an insulator 320 for insulating the stator coil 300 .

A bracket 380 for receiving and supporting the second bearing 360b is provided on a downstream side of the rotor 340 .

The bracket 380 includes, for example, a bearing accommodating part 381 for receiving and supporting the second bearing 360b and a plurality of bridges 390 formed in the bearing accommodating part 381 .

The insulator 320 is integrally formed with a vortex current suppressing part 450b for suppressing vortex generation by blocking between the plurality of bridges 390 of the bracket 380 .

The vortex current suppression part 450b is configured to extend in the axial direction to be disposed between the plurality of bridges 390 from the insulator 320 , for example.

The vortex current suppression part 450b is configured to have an extension section 470 that further extends in the axial direction from the downstream end of the bracket 380 .

The vortex current suppression part 450b is formed to have an outer surface corresponding to the outer surface of the inner housing 260 .

The radius of curvature of the outer surface of the vortex suppressor 450b is configured to be substantially the same as the radius of the inner housing 260 .

A pair of connecting pins 433 are provided in each of the vortex current suppressing units 450b, respectively.

A pair of connecting pins 433 of each of the vortex current suppressing units 450b are respectively coupled to the PCB 430 .

On the other hand, the vortex suppression portion 450b is configured with a through portion 475 through which the inner and outer sides can communicate.

Thereby, heat exchange between the inner and outer sides of the vortex current suppression unit 450b may be promoted.

According to this configuration, heat dissipation of the inner space of the vortex current suppressor 450b may be promoted.

Accordingly, cooling of the stator 280 and the rotor 340 inside the vortex suppressor 450b may be promoted.

The through portion 475 may be formed through, for example, the extension section 470 .

In this embodiment, although the case where the through portion 475 is formed in the extension section 470 is exemplified, this is only an example, and the through portion 475 is formed in the extension section ( 470) may be formed in the upstream section.

In addition, the through portion 475 may be formed in an upstream section of the extended section 470 of the vortex flow suppressing section 450 and in the extended section 470 , respectively.

According to this configuration, the vortex suppressor 450b may suppress the vortex generation of the air moved by the rotation of the impeller 210 .

Accordingly, the occurrence of a flow loss of the air moved by the impeller 210 can be suppressed. Also, noise generation due to eddy current generation can be suppressed.

In addition, the through portion 475 promotes heat dissipation of the inner space of the vortex current suppressing unit 450b (including the extended section 470), so that the inner space of the vortex current suppressing unit 450b is maintained at a relatively low temperature. can be

17 is an exploded perspective view of a motor assembly according to another embodiment of the present invention, and FIG. 18 is a perspective view of the coupled state of FIG. 17 . 17 and 18, the motor assembly 200c of another embodiment of the present invention includes an impeller 210, a housing 250, an impeller driving unit 278, a bearing 360, and a bracket 380. , a PCB 430 and a vortex suppressor 450c.

The impeller 210 and the inner housing 260 are provided inside the outer housing 251 .

One side of the inner housing 260 is disposed inside the outer housing 251 and the other side protrudes to the outside of the outer housing 251 .

The impeller driving unit 278 includes a stator 280 and a rotor 340 that is rotatably disposed with the stator 280 and a preset air gap (G).

Between the inner housing 260 and the outer housing 251, a passage 257 of air moved by the impeller 210 is formed.

The stator 280 and the rotor 340 are accommodated inside the inner housing 260 .

A coupling protrusion 297 is provided on the outer surface of the stator core 290 .

The coupling protrusion 297 is configured to protrude outward along the radial direction on the outer surface of the stator core 290 and extend in the axial direction.

A slot 267 to which the coupling protrusion 297 is received and coupled is provided in the inner housing 260 .

The stator 280 includes an insulator 320 interposed between the stator core 290 and the stator coil 300 .

The rotor 340 includes, for example, a rotating shaft 341 and a permanent magnet 345 rotating about the rotating shaft 341 .

The rotation shaft 341 is configured to extend to both sides of the permanent magnet 345 .

The rotation shaft 341 is provided with bearings 360 disposed on both sides of the permanent magnet 345 to rotatably support the rotation shaft 341 .

The bearing 360 includes a first bearing 360a and a second bearing 360b.

The first bearing 360a is disposed upstream of the permanent magnet 345 .

The second bearing 360b is disposed downstream of the permanent magnet 345 .

The first bearing 360a is supported by the inner housing 260 , and the second bearing 360b is supported by the bracket 380 .

The bracket 380 includes, for example, a bearing receiving portion 381 to which the second bearing 360b is received and coupled, and a plurality of bridges 390 formed around the bearing receiving portion 381 . .

The bearing accommodating part 381 has an outer diameter reduced compared to the outer diameter of the inner housing 260 .

The plurality of bridges 390, for example, protrude along the radial direction of the bearing receiving portion 381 and are bent from the end of the radial section 391 and the radial section 391 spaced apart along the circumferential direction, An axial section 392 extending along the axial direction is provided, respectively.

The outer surface of the axial section 392 has a circular arc cross-sectional shape corresponding to the outer diameter of the inner housing 260 .

Insertion ends 394 of the plurality of bridges 390 are respectively formed to be inserted between the inner housing 260 and the insulator 320 (second insulator 320b).

The insertion end 394 of the plurality of bridges 390 is formed by cutting the outer surface in the thickness direction so that the outer diameter can be reduced.

A bridge insertion part 325 is formed in the insulator 320 so that the insertion ends 394 of the plurality of bridges 390 can be inserted.

The bridge insertion part 325 of the insulator 320 is formed to be depressed in the radial direction so that the outer diameter of the insulator 320 is reduced.

The bridge insertion part 325 of the insulator 320 is formed to have one side open along the axial direction.

An outer surface of the plurality of bridges 390 has a protruding end 395 protruding outward from the insertion end in a radial direction.

A bridge coupling part 269 is provided in the inner housing 260 so that one region (upstream end) of each of the protruding ends 395 of the plurality of bridges 390 can be inserted and coupled.

Each bridge coupling portion 269 of the inner housing 260 has a width corresponding to the width of the plurality of bridges 390 and is cut to have a predetermined length in the axial direction.

Meanwhile, a PCB 430 is provided on one side (right side in the drawing) of the bracket 380 along the axial direction.

The PCB 430 is configured with a control program for controlling the operation of the impeller driving unit 278 (the stator 280 and the rotor 340).

A plurality of connection pins 433 electrically connected to the stator 280 (stator coil 300) are coupled to the PCB 430 .

The plurality of connection pins 433 are, for example, implemented in three pairs spaced apart along the circumferential direction.

One end of each of the plurality of connection pins 433 is inserted and coupled to the PCB 430 .

The PCB 430 includes, for example, a circuit unit connected to the plurality of connection pins 433 .

The plurality of connection pins 433 are provided with vortex current suppression units 450c to block the plurality of bridges 390 of the bracket 380 to suppress vortex generation.

Here, the vortex current suppressing part 450c may be formed to have a length such that the downstream end of the bracket 380 can be disposed to be the same as the downstream end of the bracket 380 when the bracket 380 is coupled.

In addition, the vortex suppression unit 450c may be configured to have an extension section that extends further along the axial direction so that it can be disposed on the downstream side than the downstream end of the bracket 380 when the bracket 380 is coupled. have.

A pair of connecting pins 433 are provided in each of the vortex current suppressing units 450c, respectively.

The vortex current suppression unit 450c is configured to have a circular arc cross section.

An outer surface of the vortex current suppressing part 450c is formed to correspond to an outer diameter of the inner housing 260 .

The radius of curvature of the outer surface of the vortex suppressor 450c is formed to be the same as the radius of the inner housing 260 .

A wire guide 455 for guiding the wires of each coil portion 300a of the stator coil 300 (the incoming-side wire 301a and the outgoing-side wire 301b) is provided in the eddy current suppressing unit 450c.

The wire guides 455 are respectively formed on both sides along the circumferential direction of the vortex current suppression portion 450c.

The wire guide 455 is formed to extend along the axial direction.

The vortex current suppression unit 450c may be configured to have a creepage distance increasing section 460 each having both sides spaced apart from the plurality of bridges 390 of the bracket 380 in the circumferential direction.

The wires (incoming-side wire 301a, outgoing-side wire 301b) of each coil part 300a of the stator coil 300 are guided by the wire guides 455, respectively, and are connected to the corresponding connecting pins 433, respectively. electrically connected.

Each of the vortex current suppression units 450c may be coupled such that an upstream end thereof is in face-to-face contact with a downstream end of the insulator 320 in the axial direction.

The vortex current suppressor 450c is configured to have a larger outer diameter than the outer diameter of the insulator 320 .

On the other hand, an engaging portion 480 is provided in the mutual contact region of the vortex current suppressing portion 450c and the insulator 320 to suppress lateral movement.

Accordingly, the vortex current suppressor 450c and the insulator 320 may be accurately coupled to a preset position.

The engaging portion 480 includes, for example, an axial projection 481 and the insulator 320 protruding along the axial direction on any one of the mutual contact surfaces of the insulator 320 and the vortex suppression portion 450c. and an axial projection accommodating portion 483 formed so that the axial projection 481 can be accommodated on the other one of the mutual contact surfaces of the and the vortex current suppression portion 450c.

The vortex current suppressor 450c and the insulator 320 may be adhered by, for example, an adhesive. Here, the vortex current suppressor 450c and the insulator 320 (the second insulator 320b) may be configured to be coupled to each other by fusion.

The adhesive may be applied to the mutual contact surfaces of the vortex current suppressor 450c and the insulator 320 before bonding, for example.

19 is an enlarged view of the main part of FIG. 17, and FIG. 20 is a cross-sectional view of the coupling state of the axial projection and the axial projection receiving part of FIG. 19 and 20 , the axial projection 481 may be formed to protrude in the axial direction from the vortex current suppressing part 450c, for example.

The axial projection 481 may be implemented in plurality.

In this embodiment, the axial projections 481 are exemplified in a case in which two are configured in each vortex suppressor 450c, but this is only an example, and the number may be implemented as one or three or more.

The axial projection 481 may be configured to protrude in the axial direction from the upstream end of the vortex flow suppressing part 450c, and to be spaced apart from each other in the circumferential direction.

The axial protrusion receiving part 483 may be formed to be recessed along the axial direction in the downstream end surface of the insulator 320 , for example.

The axial projection receiving portion 483 is configured to be spaced apart from each other along the circumferential direction.

With this configuration, the first bearing 360a may be received and coupled to the inside of the inner housing 260 , and the stator 280 may be received and coupled. The rotor 340 may be inserted into the stator 280 , and the vortex suppressor 450c may be attached to the insulator 320 .

When the coupling of the vortex current suppression unit 450c is completed, the wires 301a and 301b of each coil unit 300a of the stator coil 300 are guided by the wire guide 455 of the corresponding vortex current suppression unit 450c. to be electrically connected to the corresponding connection pins 433, respectively.

When the connection of the wires 301a and 301b and the connection pin 433 is completed, the plurality of bridges 390 of the bracket 380 are respectively disposed to correspond to each other in the space between the vortex current suppression part 450c in the axial direction. The bracket 380 may be coupled thereto.

The insertion end 394 of each bridge 390 may be inserted and coupled between the bridge insertion portion 325 of the insulator 320 and the inner housing 260 .

When the coupling of the bracket 380 is completed, the PCB 430 is coupled to the connection pins 433 provided in each of the vortex current suppressing units 450c.

Meanwhile, when the operation is started and the impeller 210 is rotated, the air in the upstream region of the outer housing 251 is sucked into the outer housing 251 . The sucked air is moved along the air passage 257 via the impeller 210 .

The air moving along the outer surface of the inner housing 260 is moved to the downstream side of the bracket 380 by suppressing the vortex generation by the vortex current suppressor 450c.

Some of the air moved downstream of the vortex current suppressor 450c may be moved to the inside of the vortex suppressor 450c through between the vortex current suppressor 450c and the PCB 430 .

Thereby, cooling of the inner space of the vortex current suppressor 450c may be promoted.

In the foregoing, specific embodiments of the present invention have been shown and described. However, since the present invention can be embodied in various forms without departing from the spirit or essential characteristics thereof, the embodiments described above should not be limited by the content of the detailed description.

In addition, even the embodiments not listed in the above detailed description should be broadly interpreted within the scope of the technical spirit defined in the appended claims. And, all changes and modifications included within the technical scope of the claims and their equivalents should be encompassed by the appended claims.

100: hair dryer body
110: outer case
120: inner case
130: air flow path
135: air outlet
140: electric heater
145: main pcb
150: handle
160: air intake
200,200a,200b,200c: motor assembly
210: impeller
250: housing
251: outer housing
257: movement path
260: inner housing
269: bridge coupling part
270: guide vane
278: impeller driving unit
280: stator
290: stator core
300: stator coil, 300a: coil unit
301a: lead-in wire, 301b: lead-out wire
320: insulator, 320a: first insulator, 320b: second insulator
325, 3251: Bridge insert
327: circumferential projection receiving part
340: rotor
341: axis of rotation
345: permanent magnet
360: bearing, 360a: first bearing, 360b: second bearing
361: paddle ring
363: inner ring
365: ball
380: bracket
381: Beong Ling receiving part
390: bridge
391: radius section
392: axial section
394: insertion end
395: protruding end
396: circumferential projection
430: pcb
433: connection pin
450, 450a, 450b, 450c: Vortex Suppressor
455: wire guide
460: creepage distance increase section
470: extended section
480: engaging portion
481: axial projection
483: axial projection receiving part

Claims (19)

impeller;
an outer housing in which the impeller is accommodated on one inner side;
an inner housing concentrically disposed on the inner side of the outer housing and having an air flow path formed on the outer side;
a stator accommodated in the inner housing;
a rotor accommodated in the stator and rotating the impeller;
a bearing supporting the rotation shaft of the rotor;
a bracket having a bearing accommodating part in which the bearing is accommodated and a plurality of bridges spaced apart from the outer surface of the bearing accommodating part in the circumferential direction and protruding in the axial direction to be coupled to the inner housing; and
A motor assembly comprising a; a vortex suppressor for blocking the empty space between the plurality of bridges so that the generation of a vortex of the air moved toward the bracket by the rotation of the impeller can be suppressed. According to claim 1,
The stator may include a stator core; a stator coil wound around the stator core; and an insulator interposed between the stator core and the stator coil for insulation;
The vortex suppressor is a motor assembly formed in the insulator. 3. The method of claim 2,
A motor assembly having a wire guide for guiding the wire of the stator coil on at least one side along the circumferential direction of the vortex current suppressor. 4. The method of claim 3,
The wire guide is a motor assembly that is formed on both sides along the circumferential direction of the vortex current suppressor, respectively. 4. The method of claim 3,
The vortex suppression unit, a motor assembly having a creepage distance increasing section formed to be spaced apart from the plurality of bridges on the outside of the wire guide along the circumferential direction. According to claim 1,
The outer surface of the vortex suppressor motor assembly having an arc shape. According to claim 1,
A radius of curvature of the outer surface of the vortex suppressor is a motor assembly formed to correspond to the outer diameter of the inner housing. According to claim 1,
Further comprising a PCB provided on one side of the bracket along the axial direction,
The PCB and the stator are connected by a plurality of connecting pins,
The plurality of connection pins are coupled to each other through the vortex suppressor motor assembly. 9. The method of claim 8,
The PCB is a motor assembly disposed to be spaced apart from the vortex current suppressor by a preset distance along the axial direction. 10. The method of claim 9,
An end of the vortex suppressor is disposed on the same plane as an end of the bracket along an axial direction. 9. The method of claim 8,
The vortex current suppressing part is protruded relative to the bracket along the axial direction, and the motor assembly having an extension extending so as to approach or contact the PCB. 12. The method of claim 11,
A motor assembly in which a penetrating part is formed in the vortex current suppressing part through a plate surface so that the inside and the outside can communicate in a radial direction. According to claim 1,
The bridge has an insertion end cut in the thickness direction so as to be inserted into the inner housing motor assembly is formed. According to claim 1,
The stator includes a stator core, a stator coil wound around the stator core, and an insulator provided between the stator core and the stator coil to insulate the stator coil,
A motor assembly in which a bridge insertion part into which an end of the bridge is inserted is formed in the insulator. 15. The method of claim 14,
A circumferential projection protruding in a circumferential direction is provided on any one of the bridge insertion part and the mutual contact surface of the bridge, and the other one of the bridge insertion part and the mutual contact surface of the bridge is circumferential so that the circumferential projection can be accommodated. A motor assembly provided with a direction protrusion receiving part. According to claim 1,
A plurality of connecting pins protruding along the axial direction, and further comprising a PCB provided on one side of the bracket,
The vortex current suppression part is formed of an electrical insulating member, one side is formed on the plurality of connection pins, the other side is coupled to the stator motor assembly. 17. The method of claim 16,
The stator includes a stator core, a stator coil wound around the stator core, and an insulator for insulating the stator coil,
The vortex suppression part is in axial contact with the insulator in the motor assembly. 18. The method of claim 17,
One of the mutual contact surfaces of the insulator and the vortex suppressor is provided with an axial projection protruding along the axial direction, and the other of the mutual contact surfaces of the insulator and the vortex suppressor is provided with the axial projection to be accommodated in the axial direction A motor assembly provided with a projection accommodating portion. Hair dryer body equipped with an air outlet;
a handle having an air intake and connected in communication with the hair dryer body; and
A hair dryer comprising a; the motor assembly of any one of claims 1 to 18 provided inside the handle.

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